[Academised nursing in direct patient care-but how?] / Akademisierte Pflege in der direkten Patienten/-innenversorgung ­ aber wie?

Demographic change and the resulting increase in chronic diseases, rapid developments in medicine and digitization, and the increasing shortage of skilled workers pose challenges for the German healthcare system. A rethink in patient care is required. This means that new structures, areas of action, and responsibilities must be implemented for professional nursing. The advancing academicization in nursing is leading to new role developments for professional nursing personnel in healthcare. Using the example of Klinikum Oldenburg (Oldenburg Hospital) as a maximum care provider in the region, many patients are treated in highly complex care situations that require a qualitative and evidence-based nursing practice. In order to ensure this, the concept of practice development according to McCormack, Manley, and Garbett has been implemented as a theoretical framework. Through direct evidence-based practice, complications can be reduced, which has a positive impact on mortality rate, length of stay, and readmission. Another positive factor is interprofessional collaboration and the skill-grade mix with diverse competencies. Taken together, these factors increase team satisfaction and lead to a positive outcome for patients. A prerequisite for implementing academically trained nursing professionals is good planning and preparation of the units and their stakeholders. Scientific support is also necessary to evaluate and potentially adapt the concept.

[Disorientation and delirium assessment : A secondary analysis of a prospective, observational study]. / Bedeutung der Desorientierung bei der Delireinschätzung : Sekundäranalyse einer prospektiven, observationellen Studie.

Disorientation may present as a warning sign of developing delirium. The most commonly used delirium assessment tool in Germany, the Confusion Assessment Method for Intensive Care Unit (CAM-ICU), does not rate "disorientation", since intubated patients cannot communicate verbally. However, the majority of German ICU patients are not orally intubated, so they could be examined for their orientation. This study was carried out to investigate whether the delirium feature "disorientation" in extubated patients yields diverging findings in comparison to the CAM-ICU and whether the sensitivity of the CAM-ICU may be improved when combined with the feature "disorientation" (CAM-IMC). A total of 86 paired assessments were completed in 50 extubated patients. Delirium was found in 19.8% (N = 17). The CAM-ICU had a sensitivity of 71% (95% confidence interval [CI] 44-90%) and a specificity of 100% (95-100%). Disorientation, if taken as the only delirium feature, had a sensitivity of 77% (50-93%) and a specificity of 93% (89-100%). The CAM-IMC reached a sensitivity of 88% (64-99%) and a specificity of 100% (95-100%). The receiver operating characteristics (ROC) analyses found an area under the curve (AUC) of 0.941 (95%CI 0.851-1.000) for the CAM-IMC, which was the highest compared to the other delirium tests (CAM-ICU, AUC 0.853 [0.720-0.986]; disorientation, AUC 0.868 [0.745-0.991]). This research emphasizes the importance of the feature "disorientation" for delirium assessments in patients able to verbally communicate and explains some controversial delirium ratings in daily practice. The CAM-IMC appears to be an attractive tool for delirium assessment in nonintubated patients and deserves further research.

The presynaptic active zone protein RIM1alpha is critical for normal learning and memory.

The active zone protein RIM1alpha is required both for maintaining normal probability of neurotransmitter release and for long-term presynaptic potentiation at brain synapses. We now demonstrate that RIM1alpha(-/-) mice exhibit normal coordination and anxiety-related behaviors but display severely impaired learning and memory. Mice with a synaptotagmin 1 mutation, which selectively lowers release probability, and mice with Rab3A deletion, which selectively abolishes presynaptic long-term potentiation, do not exhibit this abnormality. Our data suggest that a decrease in release probability or a loss of presynaptic LTP alone is not sufficient to cause major behavioral alterations, but the combination of presynaptic abnormalities in RIM1alpha(-/-) mice severely alters learning and memory.

Intraneuronal APP/A beta trafficking and plaque formation in beta-amyloid precursor protein and presenilin-1 transgenic mice.

Neuropil deposition of beta-amyloid peptides A beta40 and A beta42 is believed to be the key event in the neurodegenerative processes of Alzheimer's disease (AD). Since A beta seems to carry a transport signal that is required for axonal sorting of its precursor beta-amyloid precursor protein (APP), we studied the intraneuronal staining profile of A beta peptides in a transgenic mouse model expressing human mutant APP751 (KM670/671NL and V7171) and human mutant presenilin-1 (PS-1 M146L) in neurons. Using surface plasmon resonance we analyzed the A beta antibodies and defined their binding profile to APP, A beta40 and A beta42. Immunohistochemical staining revealed that intraneuronal A beta40 and A beta42 staining preceded plaque deposition, which started at 3 months of age. A beta was observed in the somatodendritic and axonal compartments of many neurons. Interestingly, the striatum, which lacks transgenic APP expression harbored many plaques at 10 months of age. This is most likely due to an APP/A beta transport problem and may be a model region to study APP/A beta trafficking as an early pathological event.

Reduction of plasma membrane glutamate transport potentiates insulin but not glucagon secretion in pancreatic islet cells.

Glutamate is generated during nutrient stimulation of pancreatic islets and has been proposed to act both as an intra- and extra-cellular messenger molecule. We demonstrate that glutamate is not co-secreted with the hormones from intact islets or purified α- and ß-cells. Fractional glutamate release was 5-50 times higher than hormone secretion. Furthermore, various hormone secretagogues did not elicit glutamate efflux. Interestingly, epinephrine even decreased glutamate release while increasing glucagon secretion. Rather than being co-secreted with hormones, we show that glutamate is mainly released via plasma membrane excitatory amino acid transporters (EAAT) by uptake reversal. Transcripts for EAAT1, 2 and 3 were present in both rat α- and ß-cells. Inhibition of EAATs by L-trans-pyrrolidine-2,4-dicarboxylate augmented intra-cellular glutamate and α-ketoglutarate contents and potentiated glucose-stimulated insulin secretion from islets and purified ß-cells without affecting glucagon secretion from α-cells. In conclusion, intra-cellular glutamate-derived metabolite pools are linked to glucose-stimulated insulin but not glucagon secretion.

Redundant functions of RIM1alpha and RIM2alpha in Ca(2+)-triggered neurotransmitter release.

Alpha-RIMs (RIM1alpha and RIM2alpha) are multidomain active zone proteins of presynaptic terminals. Alpha-RIMs bind to Rab3 on synaptic vesicles and to Munc13 on the active zone via their N-terminal region, and interact with other synaptic proteins via their central and C-terminal regions. Although RIM1alpha has been well characterized, nothing is known about the function of RIM2alpha. We now show that RIM1alpha and RIM2alpha are expressed in overlapping but distinct patterns throughout the brain. To examine and compare their functions, we generated knockout mice lacking RIM2alpha, and crossed them with previously produced RIM1alpha knockout mice. We found that deletion of either RIM1alpha or RIM2alpha is not lethal, but ablation of both alpha-RIMs causes postnatal death. This lethality is not due to a loss of synapse structure or a developmental change, but to a defect in neurotransmitter release. Synapses without alpha-RIMs still contain active zones and release neurotransmitters, but are unable to mediate normal Ca(2+)-triggered release. Our data thus demonstrate that alpha-RIMs are not essential for synapse formation or synaptic exocytosis, but are required for normal Ca(2+)-triggering of exocytosis.